Scaffolds and Cell-Based Tissue Engineering for Blood Vessel Therapy

Hsia, Kai; Yao, Chao‐Ling; Chen, Wei Min; Chen, Jian Haw; Lee, Hsinyu; Lu, Jen Her

doi:10.1159/000448169

Cited by 11 publications

(7 citation statements)

References 154 publications

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“…Although non-immunogenic autologous endothelial cells as well as SMC isolated from patients themselves would be the first choice for vessel and/or vascularized tissue engineering, the numbers of cells obtained from small vessel biopsies remain limited and, moreover, these terminally differentiated cells bear a limited proliferation potential. Even the cells isolated from umbilical veins have limited proliferation potential [ 102 , 174 ]. Thus, iPSC-derived vascular cells are an attractive source of cells that have been explored for the production of blood vessel replacements [ 175 ].…”

Section: Vascularization Strategies For Other Tissuesmentioning

confidence: 99%

iPSCs-based generation of vascular cells: reprogramming approaches and applications

Klein

2017

Cell. Mol. Life Sci.

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Recent advances in the field of induced pluripotent stem cells (iPSCs) research have opened a new avenue for stem cell-based generation of vascular cells. Based on their growth and differentiation potential, human iPSCs constitute a well-characterized, generally unlimited cell source for the mass generation of lineage- and patient-specific vascular cells without any ethical concerns. Human iPSCs-derived vascular cells are perfectly suited for vascular disease modeling studies because patient-derived iPSCs possess the disease-causing mutation, which might be decisive for full expression of the disease phenotype. The application of vascular cells for autologous cell replacement therapy or vascular engineering derived from immune-compatible iPSCs possesses huge clinical potential, but the large-scale production of vascular-specific lineages for regenerative cell therapies depends on well-defined, highly reproducible culture and differentiation conditions. This review will focus on the different strategies to derive vascular cells from human iPSCs and their applications in regenerative therapy, disease modeling and drug discovery approaches.

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Section: Vascularization Strategies For Other Tissuesmentioning

confidence: 99%

iPSCs-based generation of vascular cells: reprogramming approaches and applications

Klein

2017

Cell. Mol. Life Sci.

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“…Non-degradable synthetic materials such as expanded polytetrafluoroethylene (ePTFE), polyester (PET), and polyurethane (PU) have been used as substitutes for large blood vessels for decades due to their good mechanical properties, durability and convenient production [ 12 ]. In the treatment of superficial femoral artery occlusion diseases and renal diseases requiring hemodialysis, ePTFE stent grafts show satisfactory safety and short-term patency [ 13 ].…”

Section: Common Types and Materials Of Tevgsmentioning

confidence: 99%

“… Scaffold type Materials Advantage Disadvantage References Non-degradable ePTFE, PET, PU, etc. *Have successfully been employed for decades to bypass and reconstruct medium to large diameter vessels *Good mechanical properties, durability, and convenient production *Short of cellular communication signals and integrin-binding sites *Mechanical properties incompatible with soft tissue regeneration (may be in composite scaffolds) [ 7 , 12 , 15 , 51 ] Biodegradable PGA, PCL, etc. *Can be tailored with specific physical properties to suit particular applications *Convenient production *Appropriate mechanical properties *Toxic degradation products and loss of mechanical properties during degradation *Can't accurately mimic the in vivo microenvironment of cells *Poor regeneration of vascular wall and partial calcification [ 19 , 20 , [52] , [53] , [54] ] Natural polymer scaffold Collagen, gelatin, chitosan, etc.…”

Section: Common Types and Materials Of Tevgsmentioning

confidence: 99%

Selection of different endothelialization modes and different seed cells for tissue-engineered vascular graft

Cai

Liao

Xue

et al. 2021

Bioactive Materials

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Tissue-engineered vascular grafts (TEVGs) have enormous potential for vascular replacement therapy. However, thrombosis and intimal hyperplasia are important problems associated with TEVGs especially small diameter TEVGs (<6 mm) after transplantation. Endothelialization of TEVGs is a key point to prevent thrombosis. Here, we discuss different types of endothelialization and different seed cells of tissue-engineered vascular grafts. Meanwhile, endothelial heterogeneity is also discussed. Based on it, we provide a new perspective for selecting suitable types of endothelialization and suitable seed cells to improve the long-term patency rate of tissue-engineered vascular grafts with different diameters and lengths.

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“…В результате активируется множество сигнальных молекулярных каскадов, приводящих к структурным и физиологическим изменениям клетки, ответственных за поддержание направленной адгезии, пролиферации, опосредованной регуляции клеточного цикла [80]. В процессе эндотелизации внутренней поверхности волокнистого матрикса сосудозамещающего изделия принимают участие как клетки-предшественники, так и зрелые эндотелиальные клетки, циркулирующие в кровотоке и мигрирующие с концов анастомозов с нативным сосудом [81][82][83]. ЭК экспрессируют 13 видов интегринов, из которых в процессе адгезии с последующей эндотелизацией наиболее активно участвуют β1-субсемейство, αvβ3 и αvβ5 [84].…”

Section: экстрацеллюлярный матрикс и интегриновые рецепторыunclassified

Biodegradable small-diameter vascular graft: types of modification with bioactive molecules and RGD peptides

Senokosova

Кривкина

Антонова

et al. 2020

RJTAO

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The need for small-diameter grafts for replacing the damaged area of the blood pool is still very high. These grafts are very popular for coronary artery bypass grafting. Polymeric synthetic grafts are an alternative to autografts. A promising area of tissue engineering is the creation of a biodegradable graft. It can serve as the basis for de novo generation of vascular tissue directly in the patient’s body. Optimization of the polymer composition of products has led to improved physicomechanical and biocompatible properties of the products. However, the improvements are still far from needed. One of the decisive factors in the reliability of a small-diameter vascular graft is the early formation of endothelial lining on its inner surface, which can provide atrombogenic effect and full lumen of the future newly formed vessel. To achieve this goal, grafts are modified by incorporating bioactive molecules or functionally active peptide sequences into the polymer composition or immobilizing on its inner surface. Peptide sequences include cell adhesion site – arginine-glycine-aspartic acid (RGD peptide). This sequence is present in most extracellular matrix proteins and has a tropism for integrin receptors of endothelial cells. Many studies have shown that imitation of the functional activity of the natural extracellular matrix can promote spontaneous endothelization of the inner surface of a vascular graft. Moreover, configuration of the RGD peptide determines the survival and differentiation of endothelial cells. The linker through which the peptide is crosslinked to the polymer surface determines the bioavailability of the RGD peptide for endothelial cells.

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Scaffolds and Cell-Based Tissue Engineering for Blood Vessel Therapy

Cited by 11 publications

References 154 publications

iPSCs-based generation of vascular cells: reprogramming approaches and applications

iPSCs-based generation of vascular cells: reprogramming approaches and applications

Selection of different endothelialization modes and different seed cells for tissue-engineered vascular graft

Biodegradable small-diameter vascular graft: types of modification with bioactive molecules and RGD peptides

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